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TF Construct transfer function or convert to transfer function. Construction: SYS = TF(NUM,DEN) creates a continuous-time transfer function SYS with numerator NUM and denominator DEN. SYS is an object of type TF when NUM,DEN are numeric arrays, of type GENSS when NUM,DEN depend on tunable parameters (see REALP and GENMAT), and of type USS when NUM,DEN are uncertain (requires Robust Control Toolbox). SYS = TF(NUM,DEN,TS) creates a discrete-time transfer function with sample time TS (set TS=-1 if the sample time is undetermined). S = TF('s') specifies the transfer function H(s) = s (Laplace variable). Z = TF('z',TS) specifies H(z) = z with sample time TS. You can then specify transfer functions directly as expressions in S or Z, for example, s = tf('s'); H = exp(-s)*(s+1)/(s^2+3*s+1) SYS = TF creates an empty TF object. SYS = TF(M) specifies a static gain matrix M. You can set additional model properties by using name/value pairs. For example, sys = tf(1,[1 2 5],0.1,'Variable','q','IODelay',3) also sets the variable and transport delay. Type "properties(tf)" for a complete list of model properties, and type help tf.<PropertyName> for help on a particular property. For example, "help tf.Variable" provides information about the "Variable" property. By default, transfer functions are displayed as functions of 's' or 'z'. Alternatively, you can use the variable 'p' in continuous time and the variables 'z^-1', 'q', or 'q^-1' in discrete time by modifying the "Variable" property. Data format: For SISO models, NUM and DEN are row vectors listing the numerator and denominator coefficients in descending powers of s,p,z,q or in ascending powers of z^-1 (DSP convention). For example, sys = tf([1 2],[1 0 10]) specifies the transfer function (s+2)/(s^2+10) while sys = tf([1 2],[1 5 10],0.1,'Variable','z^-1') specifies (1 + 2 z^-1)/(1 + 5 z^-1 + 10 z^-2). For MIMO models with NY outputs and NU inputs, NUM and DEN are NY-by-NU cell arrays of row vectors where NUM{i,j} and DEN{i,j} specify the transfer function from input j to output i. For example, H = tf( {-5 ; [1 -5 6]} , {[1 -1] ; [1 1 0]}) specifies the two-output, one-input transfer function [ -5 /(s-1) ] [ (s^2-5s+6)/(s^2+s) ] Arrays of transfer functions: You can create arrays of transfer functions by using ND cell arrays for NUM and DEN above. For example, if NUM and DEN are cell arrays of size [NY NU 3 4], then SYS = TF(NUM,DEN) creates the 3-by-4 array of transfer functions SYS(:,:,k,m) = TF(NUM(:,:,k,m),DEN(:,:,k,m)), k=1:3, m=1:4. Each of these transfer functions has NY outputs and NU inputs. To pre-allocate an array of zero transfer functions with NY outputs and NU inputs, use the syntax SYS = TF(ZEROS([NY NU k1 k2...])) . Conversion: SYS = TF(SYS) converts any dynamic system SYS to the transfer function representation. The resulting SYS is always of class TF. See also TF/EXP, FILT, TFDATA, ZPK, SS, FRD, GENSS, USS, DYNAMICSYSTEM. Documentation for tf doc tf Other uses of tf control/tf DynamicSystem/tf rffilter.rffilter/tf dsp.AllpassFilter/tf idParametric/tf signal/tf dsp.Channelizer/tf mpc/tf StaticModel/tf dsp.NotchPeakFilter/tf